# Copyright 2013 by Leighton Pritchard.  All rights reserved.
# This code is part of the Biopython distribution and governed by its
# license.  Please see the LICENSE file that should have been included
# as part of this package.

"""This module provides classes to represent a KGML Pathway Map.

The KGML definition is as of release KGML v0.7.1
(http://www.kegg.jp/kegg/xml/docs/)

Classes:

    - Pathway              Specifies graph information for the pathway map
    - Relation             Specifies a relationship between two proteins or
                           KOs, or protein and compound. There is an implied
                           direction to the relationship in some cases.
    - Reaction             A specific chemical reaction between a substrate
                           and a product.
    - Entry                A node in the pathway graph
    - Graphics             Entry subelement describing its visual
                           representation
"""

import time
from itertools import chain
from xml.dom import minidom
import xml.etree.ElementTree as ET

from Bio._py3k import _is_int_or_long, _as_string


# Pathway
class Pathway(object):
    """Represents a KGML pathway from KEGG.

    Specifies graph information for the pathway map, as described in
    release KGML v0.7.1 (http://www.kegg.jp/kegg/xml/docs/)

    Attributes:
    name         KEGGID of the pathway map
    org          ko/ec/[org prefix]
    number       map number (integer)
    title        the map title
    image        URL of the image map for the pathway
    link         URL of information about the pathway
    entries      Dictionary of entries in the pathway, keyed by node ID
    reactions    Set of reactions in the pathway

    The name attribute has a restricted format, so we make it a property and
    enforce the formatting.

    The Pathway object is the only allowed route for adding/removing
    Entry, Reaction, or Relation elements.

    Entries are held in a dictionary and keyed by the node ID for the
    pathway graph - this allows for ready access via the Reaction/Relation
    etc. elements.  Entries must be added before reference by any other
    element.

    Reactions are held in a dictionary, keyed by node ID for the path.
    The elements referred to in the reaction must be added before the
    reaction itself.
    """
    def __init__(self):
        self._name = ''
        self.org = ''
        self._number = None
        self.title = ''
        self.image = ''
        self.link = ''
        self.entries = {}
        self._reactions = {}
        self._relations = set()

    def get_KGML(self):
        """Return the pathway as a string in prettified KGML format."""
        header = '\n'.join(['<?xml version="1.0"?>',
                            '<!DOCTYPE pathway SYSTEM ' +
                            '"http://www.genome.jp/kegg/xml/' +
                            'KGML_v0.7.1_.dtd">',
                            '<!-- Created by KGML_Pathway.py %s -->' %
                            time.asctime()])
        rough_xml = header + _as_string(ET.tostring(self.element, 'utf-8'))
        reparsed = minidom.parseString(rough_xml)
        return reparsed.toprettyxml(indent="  ")

    def add_entry(self, entry):
        """Add an Entry element to the pathway."""
        # We insist that the node ID is an integer
        assert _is_int_or_long(entry.id), \
            "Node ID must be an integer, got %s (%s)" % (type(entry.id),
                                                         entry.id)
        entry._pathway = self           # Let the entry know about the pathway
        self.entries[entry.id] = entry

    def remove_entry(self, entry):
        """Remove an Entry element from the pathway."""
        assert _is_int_or_long(entry.id), \
            "Node ID must be an integer, got %s (%s)" % (type(entry.id),
                                                         entry.id)
        # We need to remove the entry from any other elements that may
        # contain it, which means removing those elements
        # TODO
        del self.entries[entry.id]

    def add_reaction(self, reaction):
        """Add a Reaction element to the pathway."""
        # We insist that the node ID is an integer and corresponds to an entry
        assert _is_int_or_long(reaction.id), \
            "Node ID must be an integer, got %s (%s)" % (type(reaction.id),
                                                         reaction.id)
        assert reaction.id in self.entries, \
            "Reaction ID %d has no corresponding entry" % reaction.id
        reaction._pathway = self    # Let the reaction know about the pathway
        self._reactions[reaction.id] = reaction

    def remove_reaction(self, reaction):
        """Remove a Reaction element from the pathway."""
        assert _is_int_or_long(reaction.id), \
            "Node ID must be an integer, got %s (%s)" % (type(reaction.id),
                                                         reaction.id)
        # We need to remove the reaction from any other elements that may
        # contain it, which means removing those elements
        # TODO
        del self._reactions[reaction.id]

    def add_relation(self, relation):
        """Add a Relation element to the pathway."""
        relation._pathway = self    # Let the reaction know about the pathway
        self._relations.add(relation)

    def remove_relation(self, relation):
        """Remove a Relation element from the pathway."""
        self._relations.remove(relation)

    def __str__(self):
        """Returns a readable summary description string."""
        outstr = ['Pathway: %s' % self.title,
                  'KEGG ID: %s' % self.name,
                  'Image file: %s' % self.image,
                  'Organism: %s' % self.org,
                  'Entries: %d' % len(self.entries),
                  'Entry types:']
        for t in ['ortholog', 'enzyme', 'reaction',
                  'gene', 'group', 'compound', 'map']:
            etype = [e for e in self.entries.values() if e.type == t]
            if len(etype):
                outstr.append('\t%s: %d' % (t, len(etype)))
        return '\n'.join(outstr) + '\n'

    # Assert correct formatting of the pathway name, and other attributes
    def _getname(self):
        return self._name

    def _setname(self, value):
        assert value.startswith('path:'), \
            "Pathway name should begin with 'path:', got %s" % value
        self._name = value

    def _delname(self):
        del self._name
    name = property(_getname, _setname, _delname,
                    "The KEGGID for the pathway map.")

    def _getnumber(self):
        return self._number

    def _setnumber(self, value):
        self._number = int(value)

    def _delnumber(self):
        del self._number
    number = property(_getnumber, _setnumber, _delnumber,
                      "The KEGG map number.")

    @property
    def compounds(self):
        """Get a list of entries of type compound."""
        return [e for e in self.entries.values() if e.type == 'compound']

    @property
    def maps(self):
        """Get a list of entries of type map."""
        return [e for e in self.entries.values() if e.type == 'map']

    @property
    def orthologs(self):
        """Get a list of entries of type ortholog."""
        return [e for e in self.entries.values() if e.type == 'ortholog']

    @property
    def genes(self):
        """Get a list of entries of type gene."""
        return [e for e in self.entries.values() if e.type == 'gene']

    @property
    def reactions(self):
        """Get a list of reactions in the pathway."""
        return self._reactions.values()

    @property
    def reaction_entries(self):
        """Get a list of entries corresponding to each reaction
           in the pathway.
        """
        return [self.entries[i] for i in self._reactions]

    @property
    def relations(self):
        """Get a list of relations in the pathway."""
        return list(self._relations)

    @property
    def element(self):
        """Return the Pathway as a valid KGML element."""
        # The root is this Pathway element
        pathway = ET.Element('pathway')
        pathway.attrib = {'name': self._name,
                          'org': self.org,
                          'number': str(self._number),
                          'title': self.title,
                          'image': self.image,
                          'link': self.link,
                          }
        # We add the Entries in node ID order
        for eid, entry in sorted(self.entries.items()):
            pathway.append(entry.element)
        # Next we add Relations
        for relation in self._relations:
            pathway.append(relation.element)
        for eid, reaction in sorted(self._reactions.items()):
            pathway.append(reaction.element)
        return pathway

    @property
    def bounds(self):
        """Coordinate bounds for all Graphics elements in the Pathway.

        Returns the [(xmin, ymin), (xmax, ymax)] coordinates for all
        Graphics elements in the Pathway
        """
        xlist, ylist = [], []
        for b in [g.bounds for g in self.entries.values()]:
            xlist.extend([b[0][0], b[1][0]])
            ylist.extend([b[0][1], b[1][1]])
        return [(min(xlist), min(ylist)),
                (max(xlist), max(ylist))]


# Entry
class Entry(object):
    """Represent an Entry from KGML.

    Each Entry element is a node in the pathway graph, as described in
    release KGML v0.7.1 (http://www.kegg.jp/kegg/xml/docs/)

    Attributes:
        - id           The ID of the entry in the pathway map (integer)
        - names        List of KEGG IDs for the entry
        - type         The type of the entry
        - link         URL of information about the entry
        - reaction     List of KEGG IDs of the corresponding reactions
                       (integer)
        - graphics     List of Graphics objects describing the Entry's visual
                       representation
        - components   List of component node ID for this Entry ('group')
        - alt          List of alternate names for the Entry

    NOTE: The alt attribute represents a subelement of the substrate and
    product elements in the KGML file
    """
    def __init__(self):
        self._id = None
        self._names = []
        self.type = ''
        self.image = ''
        self.link = ''
        self.graphics = []
        self.components = set()
        self.alt = []
        self._pathway = None
        self._reactions = []

    def __str__(self):
        """Return readable descriptive string."""
        outstr = ['Entry node ID: %d' % self.id,
                  'Names: %s' % self.name,
                  'Type: %s' % self.type,
                  'Components: %s' % self.components,
                  'Reactions: %s' % self.reaction,
                  'Graphics elements: %d %s' % (len(self.graphics),
                                                self.graphics)]
        return '\n'.join(outstr) + '\n'

    def add_component(self, element):
        """Add an element to the entry.

        If the Entry is already part of a pathway, make sure
        the component already exists.
        """
        if self._pathway is not None:
            assert element.id in self._pathway.entries, \
                "Component %s is not an entry in the pathway" % element.id
        self.components.add(element)

    def remove_component(self, value):
        """Remove the entry with the passed ID from the group."""
        self.components.remove(value)

    def add_graphics(self, entry):
        """Add the Graphics entry."""
        self.graphics.append(entry)

    def remove_graphics(self, entry):
        """Remove the Graphics entry with the passed ID from the group."""
        self.graphics.remove(entry)

    # Names may be given as a space-separated list of KEGG identifiers
    def _getname(self):
        return ' '.join(self._names)

    def _setname(self, value):
        self._names = value.split()

    def _delname(self):
        self._names = []
    name = property(_getname, _setname, _delname,
                    "List of KEGG identifiers for the Entry.")

    # Reactions may be given as a space-separated list of KEGG identifiers
    def _getreaction(self):
        return ' '.join(self._reactions)

    def _setreaction(self, value):
        self._reactions = value.split()

    def _delreaction(self):
        self._reactions = []
    reaction = property(_getreaction, _setreaction, _delreaction,
                        "List of reaction KEGG IDs for this Entry.")

    # We make sure that the node ID is an integer
    def _getid(self):
        return self._id

    def _setid(self, value):
        self._id = int(value)

    def _delid(self):
        del self._id
    id = property(_getid, _setid, _delid,
                  "The pathway graph node ID for the Entry.")

    @property
    def element(self):
        """Return the Entry as a valid KGML element."""
        # The root is this Entry element
        entry = ET.Element('entry')
        entry.attrib = {'id': str(self._id),
                        'name': self.name,
                        'link': self.link,
                        'type': self.type
                        }
        if len(self._reactions):
            entry.attrib['reaction'] = self.reaction
        if len(self.graphics):
            for g in self.graphics:
                entry.append(g.element)
        if len(self.components):
            for c in self.components:
                entry.append(c.element)
        return entry

    @property
    def bounds(self):
        """Coordinate bounds for all Graphics elements in the Entry.

        Return the [(xmin, ymin), (xmax, ymax)] co-ordinates for the Entry
        Graphics elements.
        """
        xlist, ylist = [], []
        for b in [g.bounds for g in self.graphics]:
            xlist.extend([b[0][0], b[1][0]])
            ylist.extend([b[0][1], b[1][1]])
        return [(min(xlist), min(ylist)),
                (max(xlist), max(ylist))]

    @property
    def is_reactant(self):
        """Does this Entry participate in any reaction in parent pathway?

        Returns True if the Entry participates in any reaction of its
        parent Pathway
        """
        for rxn in self._pathway.reactions:
            if self._id in rxn.reactant_ids:
                return True
        return False


# Component
class Component(object):
    """An Entry subelement used to represents a complex node.

    A subelement of the Entry element, used when the Entry is a complex
    node, as described in release KGML v0.7.1
    (http://www.kegg.jp/kegg/xml/docs/)

    The Component acts as a collection (with type 'group', and typically
    its own Graphics subelement), having only an ID.
    """
    def __init__(self, parent):
        self._id = None
        self._parent = parent

    # We make sure that the node ID is an integer
    def _getid(self):
        return self._id

    def _setid(self, value):
        self._id = int(value)

    def _delid(self):
        del self._id

    id = property(_getid, _setid, _delid,
                  "The pathway graph node ID for the Entry")

    @property
    def element(self):
        """Return the Component as a valid KGML element."""
        # The root is this Component element
        component = ET.Element('component')
        component.attrib = {'id': str(self._id)}
        return component


# Graphics
class Graphics(object):
    """An Entry subelement used to represents the visual representation.

    A subelement of Entry, specifying its visual representation, as
    described in release KGML v0.7.1 (http://www.kegg.jp/kegg/xml/docs/)

    Attributes:
    name         Label for the graphics object
    x            X-axis position of the object (int)
    y            Y-axis position of the object (int)
    coords       polyline co-ordinates, list of (int, int) tuples
    type         object shape
    width        object width (int)
    height       object height (int)
    fgcolor      object foreground color (hex RGB)
    bgcolor      object background color (hex RGB)

    Some attributes are present only for specific graphics types.  For
    example, line types do not (typically) have a width.
    We permit non-DTD attributes and attribute settings, such as

    dash         List of ints, describing an on/off pattern for dashes
    """
    def __init__(self, parent):
        self.name = ''
        self._x = None
        self._y = None
        self._coords = None
        self.type = ''
        self._width = None
        self._height = None
        self.fgcolor = ''
        self.bgcolor = ''
        self._parent = parent

    # We make sure that the XY coordinates, width and height are numbers
    def _getx(self):
        return self._x

    def _setx(self, value):
        self._x = float(value)

    def _delx(self):
        del self._x
    x = property(_getx, _setx, _delx,
                 "The X coordinate for the graphics element.")

    def _gety(self):
        return self._y

    def _sety(self, value):
        self._y = float(value)

    def _dely(self):
        del self._y
    y = property(_gety, _sety, _dely,
                 "The Y coordinate for the graphics element.")

    def _getwidth(self):
        return self._width

    def _setwidth(self, value):
        self._width = float(value)

    def _delwidth(self):
        del self._width
    width = property(_getwidth, _setwidth, _delwidth,
                     "The width of the graphics element.")

    def _getheight(self):
        return self._height

    def _setheight(self, value):
        self._height = float(value)

    def _delheight(self):
        del self._height
    height = property(_getheight, _setheight, _delheight,
                      "The height of the graphics element.")

    # We make sure that the polyline co-ordinates are integers, too
    def _getcoords(self):
        return self._coords

    def _setcoords(self, value):
        clist = [int(e) for e in value.split(',')]
        self._coords = [tuple(clist[i:i + 2]) for i in range(0, len(clist), 2)]

    def _delcoords(self):
        del self._coords
    coords = property(_getcoords, _setcoords, _delcoords,
                      "Polyline coordinates for the graphics element.")

    # Set default colors
    def _getfgcolor(self):
        return self._fgcolor

    def _setfgcolor(self, value):
        if value == 'none':
            self._fgcolor = '#000000'  # this default defined in KGML spec
        else:
            self._fgcolor = value

    def _delfgcolor(self):
        del self._fgcolor
    fgcolor = property(_getfgcolor, _setfgcolor, _delfgcolor,
                       "Foreground color.")

    def _getbgcolor(self):
        return self._bgcolor

    def _setbgcolor(self, value):
        if value == 'none':
            self._bgcolor = '#000000'  # this default defined in KGML spec
        else:
            self._bgcolor = value

    def _delbgcolor(self):
        del self._bgcolor
    bgcolor = property(_getbgcolor, _setbgcolor, _delbgcolor,
                       "Background color.")

    @property
    def element(self):
        """Return the Graphics as a valid KGML element."""
        # The root is this Component element
        graphics = ET.Element('graphics')
        if isinstance(self.fgcolor, str):  # Assumes that string is hexstring
            fghex = self.fgcolor
        else:  # Assumes ReportLab Color object
            fghex = '#' + self.fgcolor.hexval()[2:]
        if isinstance(self.bgcolor, str):  # Assumes that string is hexstring
            bghex = self.bgcolor
        else:  # Assumes ReportLab Color object
            bghex = '#' + self.bgcolor.hexval()[2:]
        graphics.attrib = {'name': self.name,
                           'type': self.type,
                           'fgcolor': fghex,
                           'bgcolor': bghex}
        for (n, attr) in [('x', '_x'), ('y', '_y'),
                          ('width', '_width'), ('height', '_height')]:
            if getattr(self, attr) is not None:
                graphics.attrib[n] = str(getattr(self, attr))
        if self.type == 'line':  # Need to write polycoords
            graphics.attrib['coords'] = \
                ','.join([str(e) for e in chain.from_iterable(self.coords)])
        return graphics

    @property
    def bounds(self):
        """Coordinate bounds for the Graphics element.

        Return the bounds of the Graphics object as an [(xmin, ymin),
        (xmax, ymax)] tuple.  Co-ordinates give the centre of the
        circle, rectangle, roundrectangle elements, so we have to
        adjust for the relevant width/height.
        """
        if self.type == 'line':
            xlist = [x for x, y in self.coords]
            ylist = [y for x, y in self.coords]
            return [(min(xlist), min(ylist)),
                    (max(xlist), max(ylist))]
        else:
            return [(self.x - self.width * 0.5, self.y - self.height * 0.5),
                    (self.x + self.width * 0.5, self.y + self.height * 0.5)]

    @property
    def centre(self):
        """Return the centre of the Graphics object as an (x, y) tuple."""
        return (0.5 * (self.bounds[0][0] + self.bounds[1][0]),
                0.5 * (self.bounds[0][1] + self.bounds[1][1]))


# Reaction
class Reaction(object):
    """A specific chemical reaction with substrates and products.

    This describes a specific chemical reaction between one or more
    substrates and one or more products.

    Attributes:
    id             Pathway graph node ID of the entry
    names          List of KEGG identifier(s) from the REACTION database
    type           String: reversible or irreversible
    substrate      Entry object of the substrate
    product        Entry object of the product
    """
    def __init__(self):
        self._id = None
        self._names = []
        self.type = ''
        self._substrates = set()
        self._products = set()
        self._pathway = None

    def __str__(self):
        """Return an informative human-readable string."""
        outstr = ['Reaction node ID: %s' % self.id,
                  'Reaction KEGG IDs: %s' % self.name,
                  'Type: %s' % self.type,
                  'Substrates: %s' %
                  ','.join([s.name for s in self.substrates]),
                  'Products: %s' %
                  ','.join([s.name for s in self.products]),
                  ]
        return '\n'.join(outstr) + '\n'

    def add_substrate(self, substrate_id):
        """Add a substrate, identified by its node ID, to the reaction."""
        if self._pathway is not None:
            assert int(substrate_id) in self._pathway.entries, \
                "Couldn't add substrate, no node ID %d in Pathway" % \
                int(substrate_id)
        self._substrates.add(substrate_id)

    def add_product(self, product_id):
        """Add a product, identified by its node ID, to the reaction."""
        if self._pathway is not None:
            assert int(product_id) in self._pathway.entries, \
                "Couldn't add product, no node ID %d in Pathway" % product_id
        self._products.add(int(product_id))

    # The node ID is also the node ID of the Entry that corresponds to the
    # reaction; we get the corresponding Entry when there is an associated
    # Pathway
    def _getid(self):
        return self._id

    def _setid(self, value):
        self._id = int(value)

    def _delid(self):
        del self._id
    id = property(_getid, _setid, _delid,
                  "Node ID for the reaction.")

    # Names may show up as a space-separated list of several KEGG identifiers
    def _getnames(self):
        return ' '.join(self._names)

    def _setnames(self, value):
        self._names.extend(value.split())

    def _delnames(self):
        del self.names
    name = property(_getnames, _setnames, _delnames,
                    "List of KEGG identifiers for the reaction.")

    # products and substrates are read-only properties, returning lists
    # of Entry objects
    @property
    def substrates(self):
        """Return list of substrate Entry elements."""
        return [self._pathway.entries[sid] for sid in self._substrates]

    @property
    def products(self):
        """Return list of product Entry elements."""
        return [self._pathway.entries[pid] for pid in self._products]

    @property
    def entry(self):
        """Return the Entry corresponding to this reaction."""
        return self._pathway.entries[self._id]

    @property
    def reactant_ids(self):
        """Return a list of substrate and product reactant IDs."""
        return self._products.union(self._substrates)

    @property
    def entry(self):
        """Return the Entry corresponding to this reaction."""
        return self._pathway.entries[self._id]

    @property
    def element(self):
        """Return KGML element describing the Reaction."""
        # The root is this Relation element
        reaction = ET.Element('reaction')
        reaction.attrib = {'id': str(self.id),
                           'name': self.name,
                           'type': self.type}
        for s in self._substrates:
            substrate = ET.Element('substrate')
            substrate.attrib['id'] = str(s)
            substrate.attrib['name'] = self._pathway.entries[s].name
            reaction.append(substrate)
        for p in self._products:
            product = ET.Element('product')
            product.attrib['id'] = str(p)
            product.attrib['name'] = self._pathway.entries[p].name
            reaction.append(product)
        return reaction


# Relation
class Relation(object):
    """A relationship between to products, KOs, or protein and compound.

    This describes a relationship between two products, KOs, or protein
    and compound, as described in release KGML v0.7.1
    (http://www.kegg.jp/kegg/xml/docs/)

    Attributes:

        - entry1       The first Entry object node ID defining the
                       relation (int)
        - entry2       The second Entry object node ID defining the
                       relation (int)
        - type         The relation type
        - subtypes     List of subtypes for the relation, as a list of
                       (name, value) tuples
    """
    def __init__(self):
        self._entry1 = None
        self._entry2 = None
        self.type = ''
        self.subtypes = []
        self._pathway = None

    def __str__(self):
        """A useful human-readable string."""
        outstr = ['Relation (subtypes: %d):' % len(self.subtypes),
                  'Entry1:', str(self.entry1),
                  'Entry2:', str(self.entry2)]
        for s in self.subtypes:
            outstr.extend(['Subtype: %s' % s[0], str(s[1])])
        return '\n'.join(outstr)

    # Properties entry1 and entry2
    def _getentry1(self):
        if self._pathway is not None:
            return self._pathway.entries[self._entry1]
        return self._entry1

    def _setentry1(self, value):
        self._entry1 = int(value)

    def _delentry1(self):
        del self._entry1
    entry1 = property(_getentry1, _setentry1, _delentry1,
                      "Entry1 of the relation.")

    def _getentry2(self):
        if self._pathway is not None:
            return self._pathway.entries[self._entry2]
        return self._entry2

    def _setentry2(self, value):
        self._entry2 = int(value)

    def _delentry2(self):
        del self._entry2
    entry2 = property(_getentry2, _setentry2, _delentry2,
                      "Entry2 of the relation.")

    @property
    def element(self):
        """Return KGML element describing the Relation."""
        # The root is this Relation element
        relation = ET.Element('relation')
        relation.attrib = {'entry1': str(self._entry1),
                           'entry2': str(self._entry2),
                           'type': self.type}
        for (name, value) in self.subtypes:
            subtype = ET.Element('subtype')
            subtype.attrib[name] = str(value)
            relation.append(subtype)
        return relation
